Gas-liquid equilibration apparatus

ABSTRACT

Standards solutions and test samples are necessary for blood gas analyzers. Production of such standards and test samples has only been possible with relatively expensive apparatus. Such standards and test samples are provided herein by apparatus 10 which equilibrates a liquid 12 with a gas 14. The apparatus 10 includes a barrel 16 open at a first end 18 and at a second end 20. A piston 22 fits matingly reciprocally within the barrel 16. A flow control 26 allows the gas 14 to flow into the second end 20 of the barrel 16 and prevents the liquid 12 from flowing out of the second end 20 of the barrel 16. The gas 14 is allowed to flow out of the barrel 16 above a liquid level 44 therein. A method utilizing the apparatus 10 to prepare standard and test sample solutions is also set out.

CROSS-REFERENCE

This application is a continuation-in-part of copending application Ser. No. 7,768, filed Jan. 30, 1979, now U.S. Pat. No. 4,253,845, issued Mar. 3, 1981.

TECHNICAL FIELD

This invention relates to an apparatus for quickly and inexpensively equilibrating a sample of liquid with a gas. Such apparatus is particularly useful for preparing standard and test solutions for calibrating blood gas analysis instruments.

BACKGROUND ART

There are a number of equilibrators known for preparing a calibration standard and one or more test samples for a blood gas analyzer. In one such apparatus, the sample or standard is prepared by blowing gas onto the surface of a solution held in a tube or other type of cell, while the solution is being oscillated or spun to increase the gas-liquid contact area. Such an apparatus is relatively complicated and expensive, requiring means for accomplishing the spinning, among other things. Also, a relatively long time is required to accomplish equilibration, since even with spinning, the available surface area for absorption of the gas is relatively small. Thus, each standard or test sample generally requires from 20-30 minutes to equilibrate. Further, it is customary to prepare one standard and two test samples in each 8 hour shift, thus leading to a down time of 1 to 11/2 hours per shift for preparing samples for the calibration of a blood gas analyzer and for the testing thereof.

Another prior art gas-liquid equilibrator will produce samples in a much shorter period of time by bubbling gas into a cell below the surface of the liquid being equilibrated therewith. The cell itself is generally of a polymeric material and is matingly held within a cavity in a block of copper or other heat conductive metal. Equilibration time is fast and more than one standard or test sample can be produced simultaneously through providing a plurality of bores in the copper block and a plurality of gas lines for delivering gas, one for delivering gas beneath the surface of each of the solutions in each of the cells. While an apparatus as just described has significant advantages over other prior art apparatus, the solutions prepared in the cells of such an apparatus must be capped and transferred elsewhere by pouring or by being sucked up into a syringe or the like. While this can be readily carried out by a trained technician, it does introduce a possibility for operator error.

DISCLOSURE OF INVENTION

The present invention is directed to overcoming one or more of the problems as set forth above.

According to the present invention, an improvement is provided in a syringe apparatus which has a piston reciprocally matingly fitting within a barrel. The improvement comprises flow control means for allowing a gas to flow into a downfacing end of the barrel and for preventing flow of a liquid out of the downfacing end of the barrel. Means are also provided for allowing the gas to flow out of the barrel above a level of the liquid held therein.

Also, according to the present invention, a method is provided of equilibrating a gas with a liquid which fills a generally vertical barrel up to a liquid level therein, the barrel having a piston reciprocally matingly fitting therein and having means for allowing the gas to flow thereoutof above the liquid level therein. The method comprises flowing the gas upwardly through the liquid from an originally generally downwardly facing end of the barrel while preventing the liquid from flowing downwardly out of the barrel under the force of gravity until a desired degree of equilibration has been obtained. The gas flowing is halted while the liquid flow preventing is continued. The gas flow allowing means is blocked off, the barrel is inverted, and the liquid flow preventing is stopped. The piston is then advanced sufficiently to expel any remaining gas from between the piston and the originally generally downwardly facing, and now generally upwardly facing, end of the barrel.

It is desirable to have an inexpensive and easy to use apparatus wherein a liquid can be equilibrated with a gas. It is also desirable that the apparatus be such that the liquid is in a proper container for use as a standard test sample for insertion into a blood gas analyzer without any intermediate transfer step. And, it is desirable that the above be accomplishable in a relatively short period of time, whereby standard and test sample solutions can be prepared without excessive down time.

BRIEF DESCRIPTION OF DRAWINGS

The invention will be better understood by reference to the figures of the drawings, wherein like numbers denote like parts throughout, and wherein:

FIG. 1 illustrates, in side view, partially in section and partially schematically, an improvement in accordance with an embodiment of the present invention;

FIG. 2 illustrates an alternate embodiment of a portion of an improvement in accordance with the present invention;

FIG. 3 illustrates, in exploded side-sectional view, details of an improvement in accordance with an embodiment of the present invention;

FIG. 4 illustrates a view taken along the line IV--IV of FIG. 3;

FIG. 5 illustrates, in side-sectional view, an improvement in accordance with an alternate embodiment of the present invention;

FIG. 6 illustrates, in exploded view, a detail in the structure shown in FIG. 1;

FIG. 7 illustrates in side-sectional view, auxiliary apparatus useful with an embodiment of the present invention;

FIG. 8 illustrates, in exploded side-sectional view, an alternate embodiment of the present invention; and

FIG. 9 illustrates, in side partial view, partially in section and partially schematically, an improvement utilizing the embodiment of FIG. 8.

REST MODE FOR CARRYING OUT THE INVENTION

Adverting first primarily to FIG. 1, there is illustrated therein an apparatus 10 in accordance with the present invention. The apparatus 10 serves for equilibrating a liquid 12 with a gas 14.

Adverting particularly to FIGS. 1 and 3, it will be seen that the apparatus 10 includes a barrel 16 which is open at a first end 18 thereof and also open at a second end 20 thereof. A piston 22 is in mating slidable reciprocal relation within the barrel 16. In essence, then, it is clear that the apparatus 10 comprises a conventional syringe 24 which comprises the piston 22 which reciprocally matingly fits within the barrel 16. The present invention modifies this conventional syringe 24 in a manner which makes it suitable for equilibrating the liquid 12 with the gas 14, and for delivering a thus equilibrated sample of the liquid 12 to a blood gas analyzer with minimum chance of any contamination thereof.

In accordance with the present invention, flow control means 26 are provided which allow the gas 14 to flow into the second end 20 of the barrel 16 and which also serve for preventing flow of the liquid 12 out of the second end 20 of the barrel 16 under the influence of gravity alone. As will be clear by reference to FIG. 3, the flow control means 26 shown therein comprises a check valve 28 which is made up of a ball 30 which fits against a seat 32. In a conventional manner, downward flow is prevented by the ball 30 sitting upon the seat 32. However, upward flow is possible, since the ball 30 then lifts off of the seat 32 due to the positive pressure from below.

Adverting briefly to FIG. 5, it will be noted that alternate flow control means 26 are illustrated therein, in particular, a membrane 34 is illustrated which is impervious to flow of the liquid 12 under the influence of gravity alone and is pervious to flow of the gas 14. Generally, the membrane 34 will have microscopic (capillary) paths therethrough, and the surface of the membrane 34 will be hydrophobic so that the liquid 12 will not wet the microscopic capillary paths, and thus will be held from flowing downwardly therethrough when only under the influence of gravity. On the other hand, the gas 14 will not be held up significantly by the microscopic or capillary paths and will simply pass upwardly therethrough against the head created by the liquid 12. Equilibration can take place in such an apparatus in not more than 3 to 4 minutes for a 10 cc. sample of an aqueous liquid 12. The membrane 34 can be selected such that when a downward force which is greater than gravity is exerted upon the liquid 12, as by forcing the piston 22 downwardly, it can be forced to flow through the membrane 34.

Whether the flow control means 26 of FIG. 3 or that of FIG. 5 is utilized, there will generally be provided means 36 for removably securing the flow control means 26 to the second end 20 of the barrel 16. Such removable securing means 36 will normally comprise screw threads 38 on the second end 20 of the barrel 16 which mate with screw threads 40 on the flow control means 26. This allows disengagement of the barrel 16 from the flow control means 26, which disengagement is desirable for allowing expulsion of excess gas 14, so that the barrel 16 is fully filled with the liquid 12 below the piston 22, after equilibration thereof with the gas 14. The liquid 12 is thereby made ready for use in a blood gas analyzer, as will be pointed out in more detail in following.

Adverting again to FIGS. 1 and 3, it will be noted that means 42 are provided for allowing the gas 14 to flow out of the barrel 16 above a liquid level 44 therein. In the embodiment illustrated in FIGS. 1 and 3, the gas flow allowing means 42 simply comprises a hole 46 through the barrel 16 intermediate the liquid level 44 and the first end 18 thereof. The hole 46 is positioned a spaced distance away from the end 18 of the barrel 16 to allow the piston 22 to move close enough to the first end 18 of the barrel 16 to allow the gas 14 to flow out of the hole 46. Both FIG. 1 and FIG. 3 illustrate the piston 22 in this retracted position. It should also be noted that if the piston 22 is moved downwardly, as illustrated for example in phantom lines in FIG. 3, then the hole 46 is blocked off and neither the liquid 12, nor the gas 14 can then flow out of the hole 46. Thus, it is apparent that the hole 46 should be near the first end 18 of the barrel 16.

Referring now to FIG. 2, it will be noted that an alternate embodiment is shown therein of the means 42 for allowing the gas 14 to flow out of the barrel 16 above the liquid level 44 therein. In particular, FIG. 2 illustrates an embodiment wherein a hole 48 passes through the piston 22. As is further illustrated in FIG. 2, the hole 48 communicates with a passage 50 which itself proceeds through a handle 52 which extends axially from the piston 22 and out of the first end 18 of the barrel 16.

Adverting again to FIG. 1, the apparatus can also include a structure 54 which defines a controlled temperature chamber 56. In the particular embodiment illustrated, the structure 54 is simply a conventional constant temperature bath filled with a liquid 58, with the temperature of the bath being sensed by a temperature sensor 60. A temperature controller 62 causes a heater 64 to heat a heating element 66, and the liquid 58 is stirred in a conventional manner by a stirrer 68. It should be noted that the structure 54 is not limited to being a conventional bath filled with liquid but can be an air filled bath, can be a cavity in a block, for example a copper cavity, hinged at the side and having a bore to mate about the barrel 16, or can be any other structure 54 which will define a controlled temperature chamber 56. Temperature control can be accomplished outside of the chamber 56, if desired, and a controlled temperature fluid can then be flowed thereinto. This allows existing constant temperature baths to be used with the apparatus 10, thus potentially reducing expenditures for new equipment.

The apparatus can also include means 70 for removably mounting the barrel 16 with the second end 20 thereof in the chamber 56 up to at least about the liquid level 44. One particularly useful mounting means 70 is illustrated in FIGS. 1, 3 and 6. As may be seen in FIGS. 1, 3 and 6, the barrel 16 may include a non-circularly symmetrical flange 72 which extends laterally therefrom intermediate the first end 18 and the second end 20 thereof. In this embodiment, the barrel removably mounting means 70 includes a barrel accepting orifice 74 in the structure 54 of a size and shape sufficient to allow the second end 20 of the barrel 16 to extend therethrough and of a size and shape sufficient to prevent passage of the flange 72 therethrough.

The barrel removably mounting means 70 also includes means 76 for removably securing the flange 72 to the structure 54 adjacent the orifice 74 with the second end 20 of the barrel 16 projecting into the chamber 56. The particular flange securing means 76 illustrated in FIGS. 1 and 6 includes a flange accepting orifice 78, generally coaxial with the barrel accepting orifice 74. The flange accepting orifice 78 is of a size to allow the second end 20 of the barrel 16 and the flange 72 to pass therethrough. The flange accepting orifice 78 is shaped to allow the flange 72 to pass therethrough only when the flange 72 is particularly oriented with respect thereto. Thus, the flange 72 might be thought of as an ear extending outwardly from the barrel 16 and the flange accepting orifice 78 would be a matching or somewhat larger opening through which the ear could pass when properly aligned.

A locking orifice 80 is provided intermediate and generally coaxial with the barrel accepting orifice 74 and the flange accepting orifice 78. The locking orifice 80 is of a size and shape to accept the flange 72 in at least two orientations. The first of said orientations corresponds to the flange 72 being oriented to pass through the flange accepting orifice 78. The second orientation corresponds to the flange 72 being oriented to not pass through the flange accepting orifice 78.

One can insert the second end 20 of the barrel 16 downwardly first through the flange accepting orifice 78, then through the locking orifice 80, and then through the barrel accepting orifice 74. The flange 72 can be aligned to pass downwardly through the flange accepting orifice 78 and through the locking orifice 80. However, the flange 72 will not pass through the barrel accepting orifice 74, and hence, the flange 72 will abut the structure 54 atop the barrel accepting orifice 74. The barrel 16 is then rotated, causing the flange 72 to rotate so that the flange 72 is out of alignment with the flange accepting orifice 78. Thereby, the flange securing means 76 removably secures the flange 72 to the structure 54 adjacent the barrel accepting orifice 74 with the second end 20 of the barrel 16 projecting into the chamber 56. A recess 81 can be provided to accept the flange 72 and to keep it from rotating into an alignment where it is not locked atop the barrel accepting orifice 74.

Adverting again to FIG. 1, it is noted that the apparatus 10 may also include a source of the pressurized gas 14, such as a conventional gas cylinder 82. Gas 14 from the cylinder 82 will pass a conventional flow regulator 84 when a valve 86 is open and then will proceed via gas delivery means 88 to the flow control means 26. It will be noted that in the embodiment shown in FIG. 1, the chamber 56 also serves as means for adjusting the temperature of the gas 14, prior to its reaching the flow control means 26, to a desired value, generally the same temperature as the liquid 12. That is, a coiled tube 90 will generally sit within the chamber 56, wherein, through heat exchange with the liquid 58 therein, the gas 14 will be adjusted to the desired temperature. The tube 90 is of sufficient length to allow the second end 20 of the barrel 16 and the flow control means 26 to be removed from the chamber 56 while they are still secured together. This is important to the method of the invention as set out in more detail below.

Adverting briefly to FIG. 7, it will be seen that a cap 92 is provided having screw threads 94 which are adapted to be screwed onto the screw threads 38 adjacent the second end 20 of the barrel 16. The cap 92 serves a purpose which will become apparent from the description of the method which follows.

Referring to FIG. 3, it will be seen that the flow control means 26 has threads 96 on a lower end 98 thereof. The threads 96 mate with threads 100 on an adapter 102 which is attached to, and receives flow of the gas 14 from, the tube 90. Thus, the tube 90 is releasably secured to the flow control means 26. This allows the tube 90 to be disconnected from the flow control means 26. The barrel 16, with the flow control means 26 attached thereto and the piston 22 removed therefrom via the first end 18 thereof, can then have the liquid 12 added thereto. The flow control means 26 assures that the liquid 12 cannot escape from the second end 20 of the barrel 16. The piston 22 is then inserted to just above the hole 46 and the adapter 102 is connected to the flow control means 26.

FIG. 8 shows another alternate control means 26. A membrane 106 is affixed within the barrel 16 adjacent its second end 20. The membrane 106 serves precisely the same purpose as does the membrane 34 of FIG. 5. The membrane 106 may be of a nature whereby a force greater than gravity, as caused by pushing the piston 22 downwardly past the hole 46, will force liquid to flow downwardly and out of the second end 20 of the barrel 16. In this manner, liquid can be expelled, when desired, into a blood gas analyzer.

FIG. 8 also shows an elastomeric capping member 108 which tightly fits over the second end 20 of the barrel 16 in sealing relation. The member 108 provides a septum 110 through which a pin or needle 112 can be inserted sufficiently to pierce the membrane 106. On removal of the needle 112, the septum 110 reseals. When the piston 22 is below the hole 46 a sealed system is thus formed from which liquid having a specific dissolved gas content can be expelled by removing the member 108. The member 108 can then be placed over the second end 20 of the barrel 16, and the integrity of the liquid in the barrel 16 is maintained, whereby other equivalent aliquots of the liquid can be expelled at later times.

Adverting to FIGS. 8 and 9, it will be noted that a sleeve 114 extends downwardly from the barrel 16 about a reduced diameter portion 116 which ends at the second end 20 of the barrel 16. The sleeve 114 has internal threads 118 which allow it to attach to external threads 120 on a lug 122 which extends into a cavity 124 formed in an adapter 126, the lug 122 and the bore 128 being sized to accept the reduced diameter portion 116 of the barrel 16. The cavity 124 is shaped and sized to reasonably tightly accept the barrel 16 when it is inserted from an upward end 132 of the adapter 126, generally in a mating fit. This provides a good heat conducting relation between the barrel 16 and the cavity 124 of the adapter 126. The external threads 120 mate with the internal threads 118 to provide a twist releasable sealed passage from the inside of the barrel 16 to the downward end 130 of the adapter 126.

The adapter 126 is useful for allowing the barrel 16 to be heated by a temperature controlled heat conductive block 134 having a bore 136 therein in which the adapter 126 fits in tight heat conductive relation. Sealing means 138, in the embodiment illustrated an O-ring 140, serves to assure a sealing fit between the adapter 126 and the bore 136. Gas of a known composition is flowed from the gas cylinder 82, via the valve 86 and flow regulator 84 to a small bore 142 which leads to a bottom 144 of the bore 136. Since the sealing means 138 is present, the gas can only flow upwardly through the bore 128. Since the threads 118 and 120 provide a sealed passage, the gas must flow upwardly through the membrane 106 and into the barrel 16. Meanwhile, since the adapter 126 fits tightly in the bore 136 and the barrel 16 fits tightly in the cavity 124, good heat conduction is provided from the block 134 to the adapter 126 to the barrel 16.

It should be noted that the adapter 126 will usually be of metallic construction for best heat conduction, whereby the O-ring 140 will supply the necessary gas tight seal. However, it is contemplated that other sealing means 138 may be provided via making the adapter 126 of relatively thin walled (to provide good heat conduction) polymeric material, e.g., an elastomer or a plastic, in which case the O-ring 138 can be eliminated since such materials can themselves form a gas tight seal to the bore 136.

METHOD

Utilizing an apparatus 10 in accordance with the present invention, a unique and advantageous method of equilibrating the gas 14 with the liquid 12 which fills the generally vertical barrel 16 up to the liquid level 44 therein, is disclosed. Briefly, with the barrel 16 being disposed generally vertically and with the liquid 12 inserted therein as explained above, the gas 14 is flowed upwardly into the second end 20 of the barrel 16 and through the liquid 12, with the second end 20 of the barrel 16 being originally the generally downwardly facing end thereof. At the same time, the liquid 12 is prevented from flowing downwardly out of the barrel 16 and more particularly out of the second end 20 thereof until a desired degree of equilibration of the gas 14 with the liquid 12 has been attained.

The flowing of the gas 14 is then halted while the preventing of the flow of the liquid 12 out of the second end 20 of the barrel 16 is continued. This can be accomplished in the FIG. 1 embodiment by disconnecting the adapter 102 from the flow control means 26 and in the FIG. 9 embodiment by closing the valve 86 or releasing the barrel 16 from the adapter 126. The gas flow allowing means, that is the hole 46, or alternately the hole 48 and passage 50, is blocked off as by the operators finger or by inserting a plug (not illustrated). The barrel 16 is then inverted, thus making the originally generally downwardly facing second end 20 of the barrel 16 into a generally upwardly facing end thereof.

The flow preventing is stopped by removal of the flow control means 26 as by screwing it off of the second end 20 of the barrel 16, forcing the piston 22 towards the second end 20 with sufficient force to force flow of the liquid 12 through the membrane 34 or 106, or piercing the membrane 106 using a needle 112. Since the barrel 16 is inverted, the liquid 12 is still retained within the barrel sitting atop the piston 22. The piston 22 is then advanced upwardly sufficiently to expel any remaining gas 14 from between the piston 22 and the second end 20 of the barrel 16. In the embodiment having the hole 46, the piston 22 travels upwardly past the hole 46, thus allowing the operator to remove his finger from the hole 46 if such is being used as a temporary stopper. The cap 92 is then screwed onto the second end 20 of the barrel 16 to cap it off or the elastomeric capping member 108 serves a similar purpose. This assures that the composition of the liquid 12 within the barrel 16 is fixed. Through utilization of the controlled temperature chamber 56 or of the block 134, the temperatures of the gas 12 and the liquid 14 are normally adjusted to a desired value prior to the flowing of the gas through the liquid 12. The capped off barrel 16 is carried to a blood gas analyzer and the liquid 12 is used as a standard or as a test sample.

It will be apparent that a plurality of syringes 24 can be utilized with a single controlled temperature chamber 56 or a single block 134 having a plurality of bores 136 whereby as many samples as are desired can be prepared at a single time. Thus, the most expensive part of the overall combination, i.e., the temperature control part, does not need to be replicated for handling additional standard or test sample solutions. Further, the barrel 16 and the piston 22 can be made of relatively inexpensive materials, for example plastic, and can be manufactured by injection holding or another inexpensive molding technique. Thereby, operator time for cleaning the equilibration apparatus is eliminated, since the barrel 16 and piston 22 are simply thrown away and replaced with new parts for subsequent equilibrations.

INDUSTRIAL APPLICABILITY

The just described apparatus is particularly useful for preparing standards and samples for blood gas analysis. In such an apparatus, the liquid 12 might be water, a buffered aqueous solution, whole blood, or serum. However, the apparatus may also find use in other environments where it is desirable to equilibrate a gas with a liquid, and to be able to seal off the resulting liquid in a fast, inexpensive and straightforward manner.

Other aspects, objects and advantages of this invention can be ascertained from a study of the drawings, the disclosure and the appended claims. 

I claim:
 1. Apparatus for equilibrating a liquid sample with gas, comprising:a barrel open at a first and at a second end thereof; a piston in mating slidable relation within said barrel; a membrane affixed in said barrel adjacent said second end thereof, said membrane being substantially impervious to flow of said liquid sample when under the influence of normal gravity and being pervious to flow of said gas; and means for allowing gas to flow out of said barrel above a liquid level therein.
 2. Apparatus as in claim 1, wherein said gas flow allowing means comprises a hole through said barrel intermediate said liquid level and said first end of said barrel, said hole being positioned to allow said piston to move enough towards said first end of said barrel to allow gas to flow out of said hole.
 3. Apparatus as in claim 2, wherein said hole is near said first end of said barrel.
 4. Apparatus as in claim 1, wherein said gas flow allowing means comprises a hole through said piston.
 5. Apparatus as in claim 1, including:a handle attached to said piston and extending axially therefrom out of said first end of said barrel.
 6. Apparatus as in claim 5, wherein said gas flow allowing means comprises a hole through said piston which communicates with a passage through said handle.
 7. Apparatus as in claim 1, further including:a capping member adapted to seal off said second end of said barrel.
 8. Apparatus as in claim 1, further including:a heat conductive block having a generally vertically extending bore; an adapter adapted to fit in said bore in heat conductive relation therewith, said adapter having a cavity formed therein having top and bottom end portions, said cavity being adapted to generally matingly accept said barrel; means for releasably sealing said second end of said barrel to said bottom end portion of said adapter; and means for conducting said gas into said bottom end portion of said cavity and into contact with a downfacing side of said membrane when said second end of said barrel is sealed to said bottom end portion of said adapter. 